This article was originally published in the January/February 1999 issue of Home Energy Magazine. Some formatting inconsistencies may be evident in older archive content.

| Back to Contents Page | Home Energy Index | About Home Energy |
| Home Energy Home Page | Back Issues of Home Energy |

Home Energy Magazine Online January/February 1999

trendsin energy

A Bright Future for Advanced Fireplaces

This integrated condensing gas fireplace is currently being tested at the Advanced Combustion Technologies Laboratory. It heats tap water, warms household air, and creates radiant heat, all at over 90% efficiency.

Figure 1. The integrated condensing gas fireplace. Water is heated in the fireplace, then travels to the water heater and the HVAC unit, where tap water and air are heated through heat exchangers. The fireplace does not have to be in use for these heat exchangers to function.

The severe ice storm of January 1998 in eastern Canada and the northeastern United States showed the benefits of efficient gas and wood fireplaces that can operate independently of electricity, and increased interest in high-performing fireplaces that supply comfortable heat during an extended power outage. Conventional fireplaces are woefully inefficient, pollute to the indoors and outdoors, and can even be dangerous. These new fireplaces overcome all three problems. As Home Energy has reported in the past (see Fireplaces: Studies in Contrast, HE Sept/Oct '94, p. 27), fireplaces that are safe, efficient, low-polluting, and attractive can be very beneficial--especially in cold-climate areas that may be subject to hazardous weather conditions.
Advances in Advanced Combustion
Recently, a few manufacturers have brought out new or enhanced models of advanced combustion wood-burning fireplaces. The best designs offer an extremely attractive flame, high energy efficiency, and the ability to utilize a renewable energy resource (intelligently harvested wood).

Unfortunately, the market has been slow to take up these new fireplaces, for three reasons. First, many builders and renovators, as well as the general public, fail to recognize the superior performance that these new fireplaces offer. Second, the general perception is that burning wood in any manner is inherently polluting. Third, installation of gas fireplaces has seen phenomenal growth in recent years because the public does not understand that some advanced wood-burning fireplaces are as good as, or even better than, many gas fireplaces.

Gas Doesn't Equal Good
Well-designed gas fireplaces offer the potential for good, efficient performance. However, in spite of manufacturers' claims, many so-called efficient gas fireplaces are not well designed. Until recently, standards for measuring gas fireplace efficiency have been inadequate or inappropriate. The Canadian Gas Fireplace Efficiency Standard, CGA-P.4, uses a laboratory procedure similar to the Annual Fuel Utilization Efficiency procedure for furnaces to measure the seasonal performance of gas fireplaces as they are normally installed in Canadian housing. This standard has already been utilized in British Columbia to determine eligibility for their Clean Choice Program, and it has resulted in P.4 efficiencies being developed for a large number of gas fireplaces.

Field trials of gas fireplaces conducted here at the Advanced Combustion Technologies Laboratory (ACT) in 1996 confirmed the performance ranges. A publication by Natural Resources Canada (NRCan) entitled All about Gas Fireplaces recommends that only gas fireplaces with a high P.4 efficiency (60% or greater) be installed. P.4 is currently being expanded to include the positive effects on efficiency of firing rate modulation, which allows the fireplace to be run during milder weather without overheating the house.

An immediate positive benefit of expanding P.4 is that most manufacturers are now making at least some gas fireplaces with good P.4 efficiencies, usually with several characteristics that add to energy efficiency, comfort, and safety in the home. These characteristics can include:

direct vents, which bring outside air directly into the firebox for combustion;

good burner turndown, which allows for a lower Btu rate and more efficient use during milding weather;

ceramic glass for radiant heat transfer from the flame to the room; and

electronic ignition or a low or easy-

to-shut-down pilot light, which cuts down on excess gas use from pilot lights.

NRCan, the gas fireplace industry, and the provincial governments are currently discussing the development of a national appliance labeling program that would make it easy for Canadian consumers to determine differences in performance, based on P.4.

At present, the P.4 standard is limited to Canada; the United States does not have a specific fireplace efficiency standard. Consequently, most efficiency levels quoted by gas fireplace manufacturers in the United States are overestimated--sometimes by a very wide margin.

New Technology for Tight Houses
For the foreseeable future, North Americans will continue to demand fireplaces in their homes. However, heat demands for new houses are getting lower and lower--in Canada, the average heat load for a new house is 40 kBtu per hour. At the same time, fireplace efficiencies are getting higher. An increasingly difficult problem with the energy-efficient fireplaces (both the advanced-combustion wood fireplace and the direct-vent gas fireplace) is how to use the fireplace without overheating the room, especially during shoulder seasons with milder outside temperatures.

One solution is to make fireplaces that act more like furnaces, with ducts running off the fireplace to other zones in the house. That way, the heat can be supplied to many areas, not just the area where the fireplace is located. At least two manufacturers, CFM and Heat-N-Glo, have recently brought out such fireplaces.

The new integrated fireplaces take this idea even further. With the almost universal demand for fireplaces in homes, but less need for heat, the existence of three separate energy sources (furnace, water heater, and fireplace) becomes problematic. The integrated fireplaces solve this problem because they can supply heat to the whole house and also heat the tap water, while giving comfort and visual pleasure in the areas where they are located (see Figure 1). They may even be able to supply fresh air for house ventilation as well, through a heat recovery ventilator built-in with a fan coil. ACT, under its Advanced Integrated Mechanical Systems (AIMS) program, is actively working with Canadian manufacturers to develop the next generation of advanced combustion, high efficiency, integrated fireplaces.

One such unit is currently being tested and modified here at ACT. It is a Canadian-designed high-efficiency gas fireplace with condensing heat recovery. It heats tap water through a secondary heat exchanger, stores hot water in a well-insulated external storage tank, warms air for space heating through an efficient fan coil, and gives comfortable radiant heat from the fireplace flame, all with efficiencies of more than 90%. This is far superior to the efficiency rate of most water heaters and midefficiency furnaces and all fireplaces. Like a midefficiency gas furnace, the device has an electric ignition, an induced-draft fan, and a high-efficiency electronically commutated motor fan set for air circulation.

Snap, Crackle, Breathe
In summary, advanced-combustion wood fireplaces and high-efficiency direct-vent gas fireplaces are now widely available. These fireplaces offer consumers a means to significantly reduce energy use and CO2 emissions while maintaining a comfortable home with an attractive fire. Many of them can even run without electricity, providing comfortable heating during extended power failures like last winter's ice storm. Finally, fireplaces employ new technology to perform multiple functions at high efficiency. All this makes the future of fireplaces very bright indeed.